Edible dispersions comprising oil and structuring agent

ABSTRACT

The invention relates to an edible dispersion having a Bostwick value of at least 4 at 15° C., wherein: 1 wt. %&lt;H3&lt;6 wt. %; 1 wt. %&lt;H2U&lt;20 wt. %; and wherein at least 30 wt. % of the H3 triglycerides consist of monoacid triglycerides; H representing long-chain saturated fatty acids containing at least 16 carbon atoms and U representing cis-unsaturated fatty acids.

TECHNICAL FIELD

The present invention relates to edible dispersions comprising oil andstructuring agent, in particular to such dispersions comprising oil andstructuring agent as continuous phase and a dispersed phase. Thedispersed phase may be an aqueous liquid (thus forming a water-in-oilemulsion) and/or a solid particulate matter (thus forming a suspension)or a combination thereof.

BACKGROUND TO THE INVENTION

Edible dispersions comprising oil and structuring agent are well known.Examples of well-known products that substantially consist of suchedible dispersions are water-in-oil emulsions, such as for instancemargarines and spreads. These edible dispersions typically have an oilphase that is a blend of liquid oil and fat that is solid at normalambient temperature (20° C.). This solid fat, often also designated ashardstock, acts as structuring agent, and its function is to stabilisethe dispersion. For a margarine or spread, ideally the structuring Agenthas such properties that it should have melted or dissolved at mouthtemperature, otherwise the product has a heavy, waxy mouthfeel. Otherknown dispersions comprising oil and structuring agent are disclosed inEP-A-775444 and WO 98/47386. Herein the dispersed phase is a dryparticulate matter, such as e.g. flour, starch, salt, spices, herbs etc.

Pourable or squeezable food products having a water phase and a fatphase are for example known as liquid frying products which are pourableor squeezable water in oil emulsions at ambient temperature. Theseproducts are for example used in shallow frying. Pourable and squeezableproducts are considered to be more easily dosed than plastic productsfor example packed in a wrapper or a tub, and are therefore desiredfrying products. The pourability or squeezability of these products isevidenced by a Bostwick value of at least 4 at 15° C. For pourableproducts, a Bostwick value of at least 7 is preferred. The method todetermine this value is illustrated in the examples.

The physical storage stability of pourable or squeezable products isconsidered an important characteristic. For example squeezable orpourable emulsions may show formation of an oil layer on top of theemulsion after storage at temperatures between 5 and 25° C. Theformation of such an oil layer is referred to as oil separation.Pourable products such as liquid frying products preferably show oilseparation of less than 7 vol %, more preferred less than 5 vol %, ontotal product after storage at 15° C. for 4 weeks.

WO01/35756 describes a pourable or squeezable food product suitable foruse in shallow frying, the described products have a Bostwick value ofat least 7. The hardstock used in the product described in the examplesof WO01/35756 is RPhe70, which is high erucic rapeseed oil hydrogenated(or hardened) to a slip melting point of 70° C. RPhe70 is unrivalled ashardstock fat not only in liquid margarine, but also in other pourablefatty dispersions consisting of a triglyceride oil in which a non-fatphase is dispersed. WO 98/47386, for example, deals with thestabilisation of a pourable dispersion, which contains herbs dispersedin an oil structured with a hardstock fat.

Although RPhe70 is considered a high quality liquid margarine hardstockfat, its use also has less favourable aspects. RPhe70 is derived fromnatural rapeseed oil which has a high erucic acid content. From anutritional point of view erucic acid containing raw materials should beavoided in the preparation of food compositions. Besides this aspect andits high price, RPhe70 has the further major drawback that it isobtained by hydrogenation, a chemical treatment which does not fit inthe present trend to avoid in food manufacture chemically processed andparticularly hydrogenated ingredients.

WO 01/05241 describes pourable fatty dispersions containing: a hardstockfat consisting of a mixture of triglycerides, characterised in that itcontains at least 5 wt. % of a first triglyceride having a meltingpoint >55° C.; at least 5 wt. % of a second triglyceride having amelting point >55° C.; at least 15 wt. % of triglycerides with adifference in chain length of the longest and shortest residue of atleast four carbon atoms; not more than 25 wt. % of triglycerides havinga melting point of 25-55° C. and with the proviso that the hardstock isnot fully hardened high erucic rapeseed oil. In table I, as acomparative example, a liquid margarine is described that contains 2 wt.% of dry fractionated palm oil stearin with a slip melting point of 52and 98 wt.% sunflower. This product was found to exhibit poor stabilityas it suffers from oil exudation. The concentration of trisaturatedtriglycerides in this product is well below 1 wt. %.

SUMMARY OF THE INVENTION

It is therefore an object of the invention to provide an edibledispersion having a Bostwick value of at least 4 at 15° C. and that hasgood stability

This object is attained according to the invention in that Edibledispersion having a Bostwick value of at least 4 at 15° C., having ascharacteristics that a) the ratio H3/H2U>0.50; b) 0.5 wt. %<H3<10 wt. %;c) 0 wt. %<H2U<20 wt. %; and d) the H3 triglycerides consist for 10 wt.% or more of monoacid triglycerides.

DETAILED DESCRIPTION OF THE INVENTION

A dispersion is herein defined as a system in which two or more phasesthat are insoluble or only slightly soluble are distributed in oneanother.

The dispersion may be an emulsion, a suspension or foam or anycombination thereof, it may be oil continuous, water continuous orbi-continuous. Preferably the dispersion is oil continuous, morepreferably an oil continuous emulsion or oil continuous suspension.

Where a solid phase is present in the dispersion according to theinvention, it is preferably a solid phase of dry particulate matter.

Where an aqueous phase is present in the dispersion according to theinvention, it is preferably a dispersed aqueous phase.

In the context of the invention the terms “fat”, “oil” and triglyceridemay be used interchangeably.

Triglycerides are molecules of glycerol esterified to 3 fatty acidresidues. Triglycerides are characterised by their fatty acidcomposition and distribution over the 3 glycerol-ester positions.

The following abbreviations for fatty acids are used herein: U standsfor cis-mono- and cis-polyunsaturated fatty acids. H stand forlong-chain saturated fatty acids, of 16 carbon atoms (C16) and longer.For example, H2U stands for a triglyceride having two long-chainsaturated fatty acids of C16 or longer and one cis-mono- orcis-polyunsaturated fatty acid.

Percentages of triglycerides, e.g. H3 and H2U are expressed andcalculated relative to the total weight of the fat phase. All otherpercentages herein are expressed and calculated relative to the totalweight of the edible dispersion.

A monoacid triglyceride is herein defined as a triglyceride that has thesame fatty acid on each position of the triglyceride.

The following nomenclature of the polymorphic are used herein:

1. α-polymorph (alpha): a form that gives only one short-spacing line inthe X-ray diffraction pattern near 4.15 Å.

2. β′-polymorph (beta′): a form that gives two short spacing lines near3.80 Å and 4.20 Å in the X-ray diffraction pattern and also shows adoublet in the 720 cm⁻¹ in the infrared absorption spectrum

3. β-polymorph (beta): a form that gives three short spacing lines near3.70, 3.85 and 4.60 in the X-ray diffraction pattern.

See for an explanation of polymorphism and the above definition:Gunstone, F. D.; Harwood, J. L.; Padley, F. B.; The Lipid Handbook,second edition, Chapman and Hall, page 405.

The invention concerns an edible dispersion comprising a fat phasehaving a Bostwick value of at least 4 at 15° C., wherein the fat phasecontains:

-   -   a) 1 wt. %<H3<6 wt. %;    -   b) 1 wt. %<H2U<20 wt. %; characterised in that    -   c) the H3 triglycerides comprise at least 30 wt. % of monoacid        triglycerides.

The amount of H2U should be in accordance with: 1 wt. %<H2U<20 wt. %.Preferably, 0.5 wt %<H2U<10 wt. %, most preferably 1.5 wt %<H2U<8 wt. %

According to a preferred embodiment, 1 wt. %<H3<5 wt. % and 1 wt.%<H2U<15 wt. %, according to a more preferred embodiment, 1.5 wt. %<H3<4and 1.5 wt %<H2U<10 wt. %.

The present dispersion typically contains H3 and H2U in weight ratio ofat least 1:5. Even more preferably the weight ratio H3:H2U is at least1:5, most preferably it is at least 1:3. The weight ratio H3:H2U usuallydoes not exceed 3:1. Preferably, said ratio does not exceed 2:1. Mostpreferably, weight ration H3:H2U does not exceed 1:1.

Preferably, the triglycerides in the dispersion are from a triglyceridesource which is not partially hydrogenated. Even more preferably, saidtriglycerides are from a triglyceride source which is not hydrogenated.Partial hydrogenation of unsaturated oils produces is accompanied by theformation of trans-unsaturated fatty acids. The present dispersion,preferably contains less than 6 wt. %, more preferably less than 4 wt. %and most preferably less than 2 wt. % of trans unsaturated fatty acids.Increasingly, consumers prefer fat products that do not containhydrogenated oils and/or trans-unsaturated fatty acids. The presentinvention enables the manufacture of pourable edible dispersions that donot contain (partially) hydrogenated oil or substantial levels oftrans-unsaturated fatty acids.

Preferably the H3-triglycerides in the edible dispersion consist ofmonoacid triglycerides for 30 wt. % or more, more preferably for 50 wt.% or more, even more preferably for 70 wt. % or more.

Advantageously, the monoacid triglycerides are 60 wt. % or more,preferably 70 wt. % or more, even more preferably 75 wt. % or moreC₁₆-monoacid triglyceride. Preferably the edible dispersion comprisesfractionated palm oil stearin, more preferably dry-fractionated palm oilstearin and/or double stage dry-fractionated palm oil stearin, morepreferably substantially consisting of double stage dry-fractionatedpalm oil stearin. Typically, the fat phase of the present dispersioncomprises at least 1 wt. %, more preferably at least 2 wt. % offractionated palm stearin. The amount of fractionated palm stearincontained in the fat phase usually does not exceed 10 wt. %. Preferably,said amount does not exceed 8 wt. %.

The edible dispersion may be formed by mixing oil, hardstock and theother phase or phases of the dispersion, such as for example an aqueousphase, a solid phase and/or a gas phase. The mixing of the ingredientsmay be done in any order, i.e. the ingredients/phases may all be mixedin one mixing step or alternatively the mixing may be executed in morethan one step. For instance an oil phase with the structuring agentparticles may be mixed and a water phase may be prepared separately andlater mixed with the oil phase.

The fat phase of the present dispersion typically contains at least 85wt. % of liquid oil. More preferably, the fat phase contains at least 90wt. %, most preferably at least 93 wt. % of liquid oil.

According to one preferred embodiment, the dispersion comprises anaqueous phase and from 40 to 90 wt. % of a fat phase on total product.

The edible dispersion according to the invention have a Bostwick valueof at least 4 at 15° C. For pourable products, a Bostwick value of atleast 9 is preferred.

The invention further relates to a process for the preparation of afat-containing edible dispersion, which may be packed in a container,wherein the ingredients of the edible dispersion are heated to melt thefat and then cooled to induce crystallisation of part of the fat phasein the dispersion, characterised in that after initial crystallisationbut before filling into the container, the dispersion is kept undershearing conditions for such time and under such shearing conditions,that the ratio: beta/(beta′+alpha+beta)>0.1. Such process is especiallysuitable for the preparation of the edible dispersions according to theinvention.

In a preferred process, the dispersion is kept under shearing conditionsfor such time and under such shearing conditions, that the ratio:beta/(beta′+alpha+beta)>0.3, preferably thatbeta/(beta′+alpha+beta)>0.5.

Preferably the edible dispersion according to the invention is a waterand oil containing emulsion, optionally including a solid phase. Theemulsions are preferably oil continuous. Examples of suitable emulsionsare table spreads, sauces, shortenings, cooking oils, and frying oils.

A stable dispersion is herein defined as a dispersion that shows an oilexudation of less than 5% after storage for 15 weeks at 15° C., measuredaccording to the method described in the examples.

A further preferred edible dispersion according to the invention is adispersion of a solid matter, preferably a dry particulate matter,dispersed in a continuous phase of oil and structuring agent. Preferredmaterial for the dry particulate matter is one or more of flour, starch,salt, herbs (e.g. dried herbs), spices and mixtures thereof. Preferablyin such dispersions, the amount of solid matter is 30-75 wt. %, morepreferably 40-65 wt. % based on total weight of the dispersion.

The amount of hardstock should be such that a suitably stable dispersionis obtained. The hardstock may be micronised fat as described inco-pending application PCT/EP2004/006544 as structuring agent, theamount in such case is preferably 1-20 wt. %, more preferably 4-12 wt. %based on total weight of the dispersion.

The invention will be further illustrated in the examples.

EXAMPLES

Measuring Oil Separation

A plastic bottle of 500 ml, width: 57 mm, height 160 mm was filled withthe sample up to a filling height of 150 mm. After four weeks storage at15° C. the thickness of the separated oil layer is measured andexpressed as vol. % on total sample volume. The vol. % is the rating foremulsion stability.

Measuring Pourability

Pourability or squeezability is measured according to the standardBostwick protocol. The Bostwick equipment consists of a 125 ml reservoirprovided with a outlet near the bottom of a horizontally placedrectangular tub and closed with a vertical barrier. The tub's bottom isprovided with a 25 cm measuring scale, extending from the outlet of thereservoir. When equipment and sample both have a temperature of 15° C.,the reservoir is filled with 125 ml of the sample after it has beenshaken by hand ten times up and down. When the closure of the reservoiris removed the sample flows from the reservoir and spreads over the tubbottom. The path length of the flow is measured after 15 seconds. Thevalue, expressed as cm per seconds is the Bostwick rating, which is usedas yard stick for pourability.

The maximum value that can be determined with this measurement is 23.

Example 1

Preparation of an Edible Water-in-Oil Emulsion

A pourable margarine was prepared with the composition shown in table 1:

TABLE 1 Composition of pourable margarine of example 1 Ingredient Amount(wt. %) Oil phase Sunflower oil 77.66 mfPOs 4.0 Lecithin Bolec MT¹ 0.18Fractionated lecithin Cetinol² 0.10 Beta-carotene (1 wt. % solution in0.063 sunflower oil) H3 on fat phase 3.26 H2U on fat phase 4.6 Fractionof mono-acid triglycerides 82 in H3 fraction Fraction of mono-acid H3fraction ~98 being C16 mono-acid Water phase Water 16.5 Sodium chloride1.5Explanation of Table 1:

The balance of all composition to 100% is water

1: Lecithin was hydrolysed soybean lecithin (Bolec MT) obtained from UMZ(Golden Hope, Netherlands)

2: Alcohol-soluble fraction from fractionation of native soybeanlecithin with alcohol; Cetinol from UMZ, Netherlands.

3: mfPos is double stage dry fractionated palm oil stearin having an IVvalue of 14 (Loders Croklaan, Netherlands)

The water phase was prepared by adding salt to distilled water which washeated to approximately 80° C. and adjusting the pH of solution from 7.7to 4.0 using 10 wt. % citric acid in water. The oil phase was preparedby dissolving the emulsifier ingredients and β-carotene in the totalamount of sunflower oil at 60° C.

The edible dispersion is processed on a pilot-plant-scale unitcomprising scraped surface heat exchangers (A-units) and a crystallizerof 3 L (pin stirrer or C-unit) and a Trefa-unit. The Trefa-unit is anaeration unit (Aeration Machine Type T-50 of Trefa Continu AeratingSystems b.v., Doesburg, Netherlands). The sequence A-A-A-C-Trefa unit.The premix was prepared in a premix tank at 55° C. In exit temperaturesfrom the A, C and Trefa units are given in table 2. The Trefa-unitintroduces nitrogen into the emulsion. The throughput of the process was80 kg/hr.

TABLE 2 Processing details for examples 1 and 2 A1- A2- A3- C- ProcessUnit unit unit unit unit Trefa Rotation speed Rpm 1000 1000 1000 1300350 Exit Temperature ° C. 12 8 5 14 15 N2 input L/hr — — — — 5.2Nitrogen content Vol % — — — — 4.5

The results in oil separation upon storage at 15° C. for 2 weeks areincluded in table 4.

Example 2

In the same way as in example 1, a pourable margarine was prepared andanalysed. Except de rotations of the C-unit was set on 1000 rpm. Thecomposition of the product of example 2 is shown in table 3:

TABLE 3 Composition of pourable margarine of example 2 Ingredient Amount(wt. %) Oil phase Sunflower oil 75.41 dfPOs 6.25 Lecithin Bolec MT¹ 0.18Fractionated lecithin Cetinol² 0.10 Beta-carotene (1 wt. % solution in0.063 sunflower oil) H3 on fat phase 2.91 H2U on fat phase 5.4 Fractionof mono-acid triglycerides 75 in H3 fraction Fraction of mono-acid H3fraction ~98 being C16 mono-acid Water phase Water 16.5 Sodium chloride1.5

As in table 1, except that dfPOs is dry fractionated palm oil stearinslip melting point of 53 degrees Celcius (Loders Crocklaan, Netherlands)

The results of examples 1 and 2 are presented in table 4.

TABLE 4 Results of examples 1 and 2 Example 1 2 Bostwick (15 s) 10 6 2weeks at 15° C. Oil separation at 15° C.: Fresh 0 0  2 weeks 0 0  4weeks 0 0  8 weeks 0.7 0 12 weeks 1.4 0 16 weeks 2.1 0

The invention claimed is:
 1. An edible dispersion comprising a fatphase, the edible dispersion being pourable and having a Bostwick valueof at least 4 at 15° C., and showing an oil exudation of less than 5%after storage for 15 weeks at 15° C.; wherein the fat phase contains atleast 90 wt % of liquid oil and: a) 1 wt. %<H3 triglycerides<6 wt. %; b)1 wt. %<H2U triglycerides<20 wt. %; and c) the H3 triglycerides compriseat least 82 wt. % of monoacid triglycerides; wherein “H” representslong-chain saturated fatty acids containing at least 16 carbon atoms and“U” represents cis-unsaturated fatty acids; wherein the triglycerides inthe fat phase are from a triglyceride source which is not hydrogenated;and wherein fractionated palm oil stearin represents at least 90 wt.% ofall hardstock present in the edible dispersion.
 2. The edible dispersionof claim 1, wherein the fat phase contains 1 wt. %<H3 triglycerides<5wt. % and 1 wt. %<H2U triglycerides<15 wt. %.
 3. The edible dispersionof claim 2, wherein the fat phase contains 1.5 wt. %<H3 triglycerides<4wt. % and 1.5 wt %<H2U triglycerides<10 wt. %.
 4. The edible dispersionof claim 1, wherein the monoacid triglycerides contain at least 60 wt. %of C₁₆-monoacid triglyceride.
 5. The edible dispersion of claim 1,wherein the weight ratio of H3 triglycerides to H2U triglyceridesexceeds 1:3.
 6. The edible dispersion of claim 1, further comprisingfractionated palm oil stearin.
 7. The edible dispersion of claim 6,wherein the fat phase comprises 1-10 wt. % of fractionated palm oilstearin.
 8. The edible dispersion of claim 6, wherein the fractionatedpalm oil stearin is dry-fractionated palm oil stearin.
 9. The edibledispersion of claim 8, wherein the fractionated palm oil stearin isdouble stage dry-fractionated palm oil stearin.
 10. The edibledispersion of claim 1, further comprising an aqueous phase and whereinthe fat phase comprises from 40 to 90 wt. % of the edible dispersion.11. The edible dispersion of claim 7, wherein the fat phase comprises2-8 wt % of fractionated palm oil stearin.
 12. An edible dispersion,comprising a fat phase, the edible dispersion being pourable and havinga Bostwick value of at least 9 at 15° C.; wherein the fat phasecomprises at least 90 wt % of liquid oil and: a) 1 wt. %<H3triglycerides<6 wt. %; b) 1 wt.%<H2U triglycerides<20 wt. %; and c) theH3 triglycerides comprise at least 82 wt. % of monoacid triglycerides;wherein “H” represents long-chain saturated fatty acids containing atleast 16 carbon atoms and “U” represents cis-unsaturated fatty acids;and wherein fractionated palm oil stearin represents at least 90% of allhardstock present in the edible dispersion.
 13. An edible dispersioncomprising a fat phase, the edible dispersion being pourable and havinga Bostwick value of at least 4 at 15° C.; wherein the fat phasecomprises at least 90 wt % of liquid oil and: a) 1 wt. %<H3triglycerides<6 wt. %; b) 1 wt. %<H2U triglycerides<20 wt. %; and c) theH3 triglycerides comprise at least 82 wt. % of monoacid triglycerides;wherein “H” represents long-chain saturated fatty acids containing atleast 16 carbon atoms and “U” represents cis-unsaturated fatty acids;wherein the triglycerides in the fat phase are from a triglyceridesource which is not hydrogenated; and wherein fractionated palm oilstearin represents at least 90 wt. % of all hardstock present in theedible dispersion.
 14. The edible dispersion of claim 1, wherein themonoacid triglycerides contain at least 98 wt. % of C₁₆-monoacidtriglyceride.
 15. The edible dispersion of claim 1, wherein the edibledispersion has a ratio ofβ-polymorph/(β′-polymorph+α-polymorph+β-polymorph)>0.5.